On the Prediction of Uniaxial Tensile Behavior Beyond the Yield Point of Wrought and Additively Manufactured Ti-6Al-4V

In this paper, phenomenological relationships are presented that permit the prediction of the plastic regime of stress–strain curves using a limited number of parameters. These relationships were obtained from both conventional (wrought + β annealed) and additively manufactured (i.e., “3D printed”)...

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Bibliographic Details
Published in:Integrating materials and manufacturing innovation 2022, Vol.11 (3), p.327-338
Main Authors: Quintana, Maria J., Temple, Andrew J., Harlow, D. Gary, Collins, Peter C.
Format: Article
Language:English
Subjects:
Additive manufacturing
Characterization and Evaluation of Materials
Chemistry and Materials Science
Electron beams
Heat treatment
Kocks–Mecking–Estrin model
Laser beam melting
Manufacturing
MATERIALS SCIENCE
mechanical properties
Metallic Materials
Nanotechnology
Parameters
Stress-strain curves
Structural Materials
Surfaces and Interfaces
Technical Article
Tensile strength
Thin Films
Three dimensional printing
Ti-6Al-4V
titanium
Titanium base alloys
True strain
True stress
Ultimate tensile strength
work hardening
Yield point
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Summary:In this paper, phenomenological relationships are presented that permit the prediction of the plastic regime of stress–strain curves using a limited number of parameters. These relationships were obtained from both conventional (wrought + β annealed) and additively manufactured (i.e., “3D printed”) Ti-6Al-4V. Three different methods of additive manufacturing have been exploited to produce the materials, including large-volume electron beam additive manufacturing, large-volume laser hot wire additive manufacturing, and small-volume selective laser melting. The general fundamental expressions are independent not only of the additive manufacturing process, but also of a wide variety of post-deposition heat treatments, however the coefficients are specific to material states. Thus, this work demonstrates that it is possible to predict not only the ultimate tensile strength, but also the full true stress, true strain curves, if certain parameters of the material are known. In general, the prediction of ultimate tensile strength are within 5% of the experimentally measured values across all additive manufacturing variants and subsequent heat treatments. The absolute values of ultimate tensile strength range from ~ 910 MPa to ~ 1170 MPa for the single alloy Ti-6Al-4V. Data representing 113 explicit samples are included in this work.
ISSN:2193-9764
2193-9772
DOI:10.1007/s40192-022-00265-4